1. Software Engineer, 10gen @brandonmblack #MongoDBDays

2. Notes to the presenter Themes for this presentation: Horizontal scale only viable approach Cover the scenarios when to shard Explain the mechanics Themes: MongoDB makes this easy MongoDB includes this functionality free Best approach to with consistency

3. Agenda Scaling Data MongoDB's Approach Architecture Configuration Mechanics

5. Examining Growth User Growth – 1995: 0.4% of the world’s population – Today: 30% of the world is online (~2.2B) – Emerging Markets & Mobile Data Set Growth – Facebook’s data set is around 100 petabytes – 4 billion photos taken in the last year (4x a decade ago)

6. Read/Write Throughput Exceeds I/O

7. Working Set Exceeds Physical Memory

8. Vertical Scalability (Scale Up)

9. Horizontal Scalability (Scale Out)

10. Data Store Scalability Custom Hardware – Oracle Custom Software – Facebook + MySQL – Google

11. Data Store Scalability Today MongoDB Auto-Sharding A data store that is – 100% Free – Publicly available – Open-source (https://github.com/mongodb/mongo) – Horizontally scalable – Application independent

13. Partitioning User defines shard key Shard key defines range of data Key space is like points on a line Range is a segment of that line

14. Data Distribution Initially 1 chunk Default max chunk size: 64mb MongoDB automatically splits & migrates chunks when max reached

15. Routing and Balancing Queries routed to specific shards MongoDB balances cluster MongoDB migrates data to new nodes

16. MongoDB Auto-Sharding Minimal effort required – Same interface as single mongod Two steps – Enable Sharding for a database – Shard collection within database

18. What is a Shard? Shard is a node of the cluster Shard can be a single mongod or a replica set

19. Config Server – Stores cluster chunk ranges and locations – Can have only 1 or 3 (production must have 3) – Not a replica set Meta Data Storage

20. Routing and Managing Data Mongos – Acts as a router / balancer – No local data (persists to config database) – Can have 1 or many

21. Sharding infrastructure

23. Example Cluster Don’t use this setup in production!  Only one Config server (No Fault Tolerance)  Shard not in a replica set (Low Availability)  Only one mongos and shard (No Performance Improvement)  Useful for development or demonstrating configuration mechanics

24. Starting the Configuration Server mongod --configsvr Starts a configuration server on the default port (27019)

25. Start the mongos Router mongos --configdb :27019 For 3 configuration servers: mongos --configdb :, :, : This is always how to start a new mongos, even if the cluster is already running

26. Start the shard database mongod --shardsvr Starts a mongod with the default shard port (27018) Shard is not yet connected to the rest of the cluster Shard may have already been running in production

27. Add the Shard On mongos:  sh.addShard(‘ :27018’) Adding a replica set:  sh.addShard(‘ / ’)

28. Verify that the shard was added db.runCommand({ listshards:1 }) { "shards" : [{"_id”: "shard0000”,"host”: ” :27018” } ], "ok" : 1 }

29. Enabling Sharding Enable sharding on a database sh.enableSharding(“ ”) Shard a collection with the given key sh.shardCollection(“.people”,{“country”:1}) Use a compound shard key to prevent duplicates sh.shardCollection(“.cars”,{“year”:1, ”uniqueid”:1})

30. Tag Aware Sharding Tag aware sharding allows you to control the distribution of your data Tag a range of shard keys sh.addTagRange(,,, ) Tag a shard sh.addShardTag(, )

32. Partitioning Remember it's based on ranges

33. Chunk is a section of the entire range

34. Chunk splitting A chunk is split once it exceeds the maximum size There is no split point if all documents have the same shard key Chunk split is a logical operation (no data is moved)

35. Balancing Balancer is running on mongos Once the difference in chunks between the most dense shard and the least dense shard is above the migration threshold, a balancing round starts

36. Acquiring the Balancer Lock The balancer on mongos takes out a “balancer lock” To see the status of these locks: use config db.locks.find({ _id: “balancer” })

37. Moving the chunk The mongos sends a moveChunk command to source shard The source shard then notifies destination shard Destination shard starts pulling documents from source shard

38. Committing Migration When complete, destination shard updates config server  Provides new locations of the chunks

39. Cleanup Source shard deletes moved data  Must wait for open cursors to either close or time out  NoTimeout cursors may prevent the release of the lock The mongos releases the balancer lock after old chunks are deleted

41. Cluster Request Routing Targeted Queries Scatter Gather Queries Scatter Gather Queries with Sort

42. Cluster Request Routing: Targeted Query

43. Routable request received

44. Request routed to appropriate shard

45. Shard returns results

46. Mongos returns results to client

47. Cluster Request Routing: Non-Targeted Query

48. Non-Targeted Request Received

49. Request sent to all shards

50. Shards return results to mongos

51. Mongos returns results to client

52. Cluster Request Routing: Non-Targeted Query with Sort

53. Non-Targeted request with sort received

54. Request sent to all shards

55. Query and sort performed locally

56. Shards return results to mongos

57. Mongos merges sorted results

58. Mongos returns results to client

60. Shard Key Shard key is immutable Shard key values are immutable Shard key must be indexed Shard key limited to 512 bytes in size Shard key used to route queries – Choose a field commonly used in queries Only shard key can be unique across shards – `_id` field is only unique within individual shard

61. Shard Key Considerations Cardinality Write Distribution Query Isolation Reliability Index Locality

62. { _id: ObjectId(), user: 123, time: Date(), subject: “...”, recipients: [], body: “...”, attachments: [] } Example: Email Storage Most common scenario, can be applied to 90% cases Each document can be up to 16MB Each user may have GBs of storage Most common query: get user emails sorted by time Indexes on {_id}, {user, time}, {recipients}

63. Example: Email Storage Cardinality Write Scaling Query Isolation Reliability Index Locality

64. Example: Email Storage Cardinality Write Scaling Query Isolation Reliability Index Locality _idDoc levelOne shard Scatter/gat her All users affected Good

65. Example: email storage Cardinality Write scaling Query isolation Reliability Index locality _idDoc levelOne shard Scatter/gat her All users affected Good hash(_id)Hash levelAll Shards Scatter/gat her All users affected Poor

66. Example: Email Storage Cardinality Write Scaling Query Isolation Reliability Index Locality _idDoc levelOne shard Scatter/gat her All users affected Good hash(_id)Hash levelAll Shards Scatter/gat her All users affected Poor userMany docsAll ShardsTargeted Some users affected Good

67. Example: Email Storage Cardinality Write Scaling Query Isolation Reliability Index Locality _idDoc levelOne shard Scatter/gat her All users affected Good hash(_id)Hash levelAll Shards Scatter/gat her All users affected Poor userMany docsAll ShardsTargeted Some users affected Good user, timeDoc levelAll ShardsTargeted Some users affected Good

69. Read/Write Throughput Exceeds I/O

70. Working Set Exceeds Physical Memory

71. Sharding Enables Scale MongoDB’s Auto-Sharding – Easy to Configure – Consistent Interface – Free and Open-Source

72. What’s next? – Hash-Based Sharding in MongoDB 2.4 (2:50pm) – Webinar: Indexing and Query Optimization (May 22 nd ) – Online Education Program – MongoDB User Group Resources https://education.10gen.com/ http://www.10gen.com/presentations http://www.10gen.com/events http://github.com/brandonblack/presentations

73. Software Engineer, 10gen @brandonmblack #MongoDBDays